Reducing the boundary layer of aerodynamic effects

ABSTRACT

Aerodynamic effects are found when air flows over objects such as aircraft and motor cars moving through ambient air. The flow of air through the objects involves issues concerned with aerodynamics. Forced circulation of air through pipes presents numerous problems of aerodynamics because of the variable behavioural modes of operation generally in subsonic mode. Opposing forces then come into play and throttle the flows, thus reducing the effectiveness of a given diameter or cross section under particularly critical conditions in the flow of gases, generally air. The flow of gases or liquids close to the walls is slowed and opposes the overall flow, creating differential flow gradients between the centre of the flow and the peripheral edges thereof. This electronic component known as an eCRT “electron convector real time” which is made up of a very fine mixture of various silica powders to which there are added metal powders, for example titanium powder, aluminium powder, these being added in very precise ratios by those skilled in the art, attracts the electrons and converts them into a vibrational mechanical mode simply through electronic affinity which attracts, transforms and directs the energy of the electrons. The method and devices of this patent can be used to correct and regulate all agitated electrons and free ions, also involved in moving fluids and gases, which devices can be used in the mechanical, aeronautical, space and marine industries and in the field of computers, food stuffs and also the sphere of medicine.

Aerodynamic effects occur when air circulates over objects such asairplanes, automobiles moving through ambient air. The flow of airthrough the objects also raises aerodynamism issues. The forced flow ofair through ducts raises numerous aerodynamic issues because of themodes of operation with variable behaviors generally in subsonic mode.Opposing forces then come into play which throttle the flows, thusreducing the effectiveness of a given diameter or cross section underparticularly critical conditions in the flow of gases, generally air.The same applies for liquids, and the terms “aeraulics” and “hydraulics”then apply. Whether it is on gaseous or liquid materials, the flow ofthe fluids is complicated on the waals of duct pipes. The flow of gasesor liquids close to the waals is slowed down and opposes the overallflow creating different flow gradients between the center of the flowsand the peripheral edges. This observation is referred to as drag, form,profile on bends for example, friction on pipe surfaces.

The interference drags caused by modifying the pressure or speed ofthese fluids inside duct pipes greatly modify the overall flow behaviorinside the cavities of the ducts, which is the subject of a correctionand regularization of the overall flow of the liquid or gaseous fluidsby the present patent application. The drag forces that oppose theoverall flow movements are corrected by a method deriving fromnanotechnology, that modifies the adhesion forces binding the fluids andthe gases to the waals of the ducts. The releasing of theelectromagnetic adhesion forces, such as the Van der Waals forces andthe polar quantum forces created by the agitated flow turbulences of themolecules, give uniform flows on all the sections of the fluid duct orducts regardless of flow rates and pressures. The fluids themselves arereleased from the forces of cohesion and tension with the waals thatmade them less fluid. The electronic forces create surface tensionsbetween the molecules themselves and the waals which slow down thefluidity. These forces contribute to the turbulences within the flow ofthe gaseous or liquid fluids and, upon contact with the waals, causeboundary layers to be created, reducing the effective overall flowsection. The variable flow of the fluids in terms of speed or densityvaries the overall flows in proportions that cut through any desiredoperating linearity, making operation unstable, unpredictable andchaotic. This instability makes synchronizing mechanical movementsdifficult, as well as the chemical balance functions of variouscomponents that have to be perfectly dosed for any carburetion systemsrequiring highly variable energy charges. An example is the intake ofair into a carburetion feed which varies strongly in terms of thenecessary air flow rate, a flow rate that is then strongly opposed bycirculation mode malfunctions within nozzles and suction ducts. Theregulation is provided by the present method deriving from understandingin nanotechnology concerning the polarity and the electrovalency chargesthat the molecules of the fluids polarize and the surface tension forcesthat are established between the molecules themselves and the waals ofthe ducts. The material of the ducts obviously interacts well. Fromrabbit skin rubbed on an ebonite rod to industry, the magnetic charges,the polar forces and the Van der Waals forces to situate the problem areforces that modify the dynamic behavior of the fluids flowing inside andoutside solid components. The surface tension ratios are opposed by theelectrical charges that are established in numerous forms includingthose known and stated by Maxwell, Laplace, Van der Waals, Lorentz andGauss, among others.

The present application directly addresses these issues of intrinsicfluctuation of electronic charge in fluids and gases applied to theforces of the ions and electrons migrating to the molecules in motion.The agitated molecules are subjected to rubbing, friction, shear andslip forces between them and on the surfaces of the waals of the objectsthat they encounter such as those of automobiles, airplanes, boats, orintake pipes of carburetion devices to give a few nonlimiting examples.

The fluctuations of the ions and electrons are of the same order insideducts, nozzles, pipes carrying fluids produced in all kinds of materialssuch as, to give nonlimiting examples, tubes made of polymer plastics oraluminum, copper, metal, to give nonlimiting examples of the productsused. The world of nanotechnology allows, through the present method,for a homogenization, a regularity of the fluidity of the overall flowsof the fluids and of the gases on the solid surfaces regardless of theoverall flow speeds required or profitably undergone, by the affixing ofat least one electronic component specific to the present application tothe surface of the moving object or to the wall of the duct or ducts ornozzles used to conduct the liquid or gaseous fluids. In the same wayas, in electronics, the transistors conduct the movement of theelectrons by the polarities and the functions of their electronreservoir insulating components and the conductors that make it possibleto circulate the electrons, the present method, through a novelelectronic component, allows for an electronic circulation whichinvolves attracting/absorbing the surplus electrons and ions, consumingthe electrons that congregate en masse through friction on the fluidsand gases and on the waals. The releasing of the polarizations of thesurplus ions and electrons on the fluids, the gases and the waalseliminates the interfaces that slow down the flows. These excesselectronic imbalances exerted on the fluids and the gases greatlypenalize the fluidity factors which are thus corrected by simpleelectronic cleaning. The cleaning of electronic polarization allows forthe ideal optimized used of carburetion. This example greatly reduces COand CO₂ pollutions and noises, the efficiencies of the engines areperceived through the torque and the power available regularly,spontaneously according to all the required energy regime modes.

The device, the electronic component, affixed to the surfaces of theobjects or of the ducts where the fluid or gas movements flow, is greedyfor ions and electrons through two essential qualities which are ahunger to attract the electrons and the ions by the inceration of copperor precious metals such as gold having a high valency with a capacity toattract the electrons and the second quality being the hunger of thepiezoelectricity which is transient to eat the energy of the ions andelectrons, piezo consisting of silicas and quartz of different kindsoscillating at high frequency through quartz crystals like diamond orsimilar. Nonlimiting example of composition for putting the method inplace. The free ions and electrons migrate toward this electroniccomponent which attracts them and consumes them through thepiezoelectricity releasing the accumulated electric charges stagnatingon the circulating fluids or gases. The electronic component istherefore the amalgam of silica/quartz likely to operate inpiezoelectricity mode with the addition of metals or components lackingelectrons and ions that naturally attract them.

This electronic component called eCRT, standing for “Electron ConvectorReal Time”, consisting of a very fine mixture of various silica powderswith the addition of metallic powders, such as, for example, titanium,aluminum powder made in very precise ratios by those skilled in the art,can be used to attract the electrons and transform them into a vibratorymechanical mode through the simple electronic affinity which attracts,transforms and directs the energy of the electrons.

The device is molded according to demand and available spaces, and thisvaries from a few grams to a few hundred grams. Uses on large masses tobe cleaned can range up to several kilos.

This molded component can have a number of composition variants thatdiffer by different percentages of silica and of different metalsaccording to the desired specific reactivity. This component or thesecomponents is/are placed on the nozzles or the surfaces in motionrelative to the fluids or gases concerned. The component can also beplaced inside ducts at the center of the flows or on the edges of theflows concerned for the desired corrections. This product is designed tooperate with no specific conductor, without an electrical wire that hasbecome pointless, since, in effect, the electronic permeability of air,of space or of the components is sufficient for the electronic ionicexchanges that are possible in these nanometric scale conditions. Theionic electronic affinity differentials do not need conductive wirebecause the ions or the electrons jump from component to component ofempty ionic or electronic space according to the affinity and electronicvalency gradients specific to each material, until the energy absorptionof the piezoelectricity of the “eCRT” product, which, after havingattracted these ions and electrons, consumes the electronic energy inmechanical vibratory form. The device can be coated with a fine layer ofplastic, polymer or paper, cardboard, an esthetic packaging or atechnical packaging to insulate it from water for example or fromchemical attack. In computers, the flows of the ions and electrons inthe wires can be likened to fluids in pipes and do not lack similarchaotic functions, which are corrected in the same way. Phase reversesoccur that oppose the flow. Corrective frames identify the “multilevelovermodulation” electronic chaos to be eliminated. These spuriousphenomena create chaotic functions in electron flows as in the fluidsthat are well known, and this, in the audio field, affects the soundqualities, which are corrected by this method and devices. The soundalterations due to spurious phenomena are now eradicated and cleaned. Inpractice, the spurious phenomena are combined in order of magnitude withthe harmonics that are no longer distinguished, mixed in the incoherentflows of the multilevel cross phases. The excess ion or electron chargesaffect in chaotic mode the initial functioning modalities of the fluidsand of the electrical information. The same applies in the imageprocessing field. Specific installation for this application is done bysimply juxtaposing the device, the novel eCRT electronic component, withthe conductive wire or wires or the simple placement of the eCRT in thedevices, the permeability acting naturally without electrical wirecoupling.

Components and applications of this method can be used to correct andregulate all usages of electrons and agitated ions in motion inelectronic physics to eliminate the complex and multilevel phaseinterferences from the field of computers to the audiovisual field andfrom the field of fluids and/or gases in motion used in the mechanical,aeronautical and space and marine industries, as well as in field offoodstuffs, and also in the medical field. All these applications have acommon reason, the self-induced effects of the polarizations of thecharges of the ionic and electronic forces in motion partly described asstated by Laplace, Maxwell, Lorenz, Van der Waals and Gauss amongothers.

1. A method which is to clean the gases and fluids flowing inside oroutside objects of ion or electron charges built up by friction in thecirculating flows of the movements, cleaning that is obtained by thepresence of a novel electronic component placed on the surface of theobjects or in the flows of the liquids or the gases, an electroniccomponent that absorbs the surpluses of the electronic or ionic chargesby the electronic affinity of the metals on the one hand and by thevoracity of the piezoelectricity of the silicas of the molded electroniccomponent, a component which, by its simple presence, provides for thereleasing of the electronic charges making the fluidity uniform tooptimize the usages of the fluids or/and of the gases used unaffected bythe fluctuations of the electronic charges that create interfaces suchas the boundary layers in aerodynamics on the surface of the nozzles orducts.
 2. A device which is an electronic component that is fixed,placed, glued to the surface of an object travelling in space such as anautomobile or an airplane, or a fixed, glued to the surface of a ductfor a fluid or air in a carburetion system for example, correcting thefluidity in linear mode, or stabilized by releasing the ions and theelectrons of the fluids or the gases flowing in the nozzles, pipes andducts, a device that is characterized by two essential qualities one ofwhich is to attract the ions or the electrons by powdered metals such asaluminum, titanium, to give nonlimiting examples, or components that areeager for electrons or ions, and by the piezoelectricity formed bydifferent silicas with high resonance frequency such as diamond whichconsumes the energy of the ions and electrons transformed intomechanical vibratory modes, a device that greatly reduces the boundarylayer thereby eliminating the chaos, the operating instability, thatcontributes to the lowering of the CO and CO₂ pollution and by anoptimization of engine efficiencies, a lowering of the noises, a devicethat is molded following the addition of silica powder and powderedmetals that are very well mixed in very precise ratios by those skilledin the art.
 3. The device as claimed in claim 2, characterized in thatthe passage of electrons or of the ions occurs naturally through theempty spaces at nanotechnology level, and at the level of the affinitiesof the electronic valences, a natural permeability, without electricalconductor.
 4. The device as claimed in claim 2 is characterized for theuse of computers and for audio-visual applications, by putting in placethe juxtaposition of the eCRT device, the novel electronic component,with the electronic wires, or its simple placement in the devices, thepermeability acting naturally without electrical coupling.
 5. The deviceas claimed in claim 2 can be coated with a fine layer of plastic,polymer or paper, cardboard, an esthetic packaging or a technicalpackaging to insulate it from water for example or from chemical attack.6. The method and devices of this patent are used to correct andregulate all the agitated free electrons and ions, also occurring in themoving fluids and gases, devices that are useful in the mechanical,aeronautical, space and marine industries and in the field of computersand foodstuffs and also in the medical field in order to limit theself-induced common effects of the polarizations of the ionic andelectronic charges hampering the movements, as stated by Laplace,Maxwell, Van der Waals, Lorenz and Gauss, among others.